Supplementary fluid feed device with automatic tandem metering valves



p 195 0. aAmuzasun 2,611,594

' SUPPLEMENTARY mum-mu DEVZGIZ WITH AUTOMATIC TANDEM METERING VALVES Filed Oct. 27, 1948 2.SHEETS-SHEET 1 Sept. 23, 1952 D 'E JANDERESQN 2,611,594

SUPPLEMENTAR! FLUID: E'EEDDEVIQE; WITH AUTOMATIC MEEM'METERING VILVES Filed OC'L 27, 1948 2 SHEETS-SHEET 2 Patentecl Sept. 23, 1952 I UiNITEiD Si-TAT-ES PATENT OFFICE SUPPLEMENTARY. FLUID WITH AUTOMATIC TKNDEM METER- DavidaE; Andersun,.1Shaker Heighten-Ohioass :sign'or to Thompson ProductS,;;I'-nc-,,.=- Gleveland 'Ohiogaeorpovation of Ohio.-

Appliuation October 2'7, 194%; Seri'aklNozfi92 (Gise e-41 E).

Tim-present invention relates to a-supplemen'-- tary fuel feeding device for use with internal combustion engines and more particularly re-' lates 'to devices f-or feeding supplementary fuel be" an internal combustion engine through a--p111 rallty of meteringvalves actuated underdifferexit-engineoperating conditionsto insure the fedi'n'gof sufiicient supplementary fuel to prevent-engine d-etenatibn and preignition.

'It'h'as' beenproposed that-supplementary f ue-1; such as mixtures of alcohol and water he inflected-into theintake mauitold cf theengine in amounts controlled by" the engine intake man- 'ifbld vacuum toprevent detonation a-n-dpre'ignitio'n' while theengineisoperating-under conditiuns 'cf high load, high speed, nrrapid acceleration. Su'c'h devices generally'employ a diaphragm-controlled 'va'lve; the-diaphragm being subject to" the intake manifold vacuum to contrek-movement of the valvein accordanc'e'with the operating characteristics of the engine.

The present invention now" provides-an improved metering device for-the feedingofi'sup- 'pleinentary fuel into an internal-combustion eng'i'ne in accnrdance with the operatin'g'condi- 'ti onsiof the engine; In generalgthedevicecomprises a casing defining-a reservoir "for' c'ontaining a pond of supplementary qfuel' introduced therein throughha float controlledwalve- 01011- nected to a suita'ble' source of supplementary position against the resistance of. a diaphragm having one surface subjected to atmospheric pressure and "the other :surface subjected to manii old intake vacuum 'of the engine. In the device of the present inventionemploying two =or m'ore' valves, the-"springs and d'iaph-ragms are so constructed and regulated that the valves are actuated. at-difierent manifold intake vacuums 'toesta'blishithe fi'ow'oi supplementary fuel from ."Lth-e reservoirito the :engine. By'x'this arrange- -ment- .more'.::efficient :feeding sci-i :slmplementary fuel is obtained: *imthazt :the. new" :of rsupnlemene tary' fuel. is. male :neamlyucorrelatei to 113113 -.actuallcperatings :cemiiticins cf the engine :tu :which the-device :is attahhed, For: example; .;the; primary -metering valve; he operable tones:- tafdlish iflow: lei supplementary fuel .at: engine intake--man1foldr:vacuums' ranging from about: 0 to about 35 -5O" inchesof water? while: the: ,secendary valve (ermines)- cperahle atmanifill-d wacuumsxnanging i-rnm 1-10 to: "VD-1:00. inche of water; i'Thusr a111- ef. the: metering: valves wane ii-pert fur *f-ull -metei:e'd 6f supplementary fuel und'er'ithose eonditiens ef low-'vacuumiwhieh area mostcomiuciue to: engine: detonatium.;and preeigniti-onwhilethe secondary valve -('or valves? remains open, after the" primary valve isclosed, at h i'gher engine vacuums tometer' a lesser amount-of f-ueliunderthe influenne of this higher vacuum.

one: specific embodiment of the: present invention: a: main--.metering valve placed in the conduit leading from the feed mg device-to the engine and is -=eentr-Qlled-' by :themanifold vacuum-vented diaphragm; The valve is operable tn be seated at relatively l'ow 'vacuum's so that fuel is primarily-passedthrough thecenduitbeyond this valveonly at these conditions where -predet-onatlen is= mest likely to seem. This primary valveis also provided wither-a by pass to permit "ii-ow of supplementary iu'el through-a restricted erificeeven though the primaryvalve itself is closed A second (it- -'ph-ragm centrolled 'val ve is-lo'cat-ef in thecon.-

duit between the primary valveand-the-engine and this valve is operah'le-to-rema-in open at manifold vacuums considera hly in excess of those -'suffieient--' tcse'at' the primary valve; with the second rvalve-also'heing seated at high =manifold vacuums, where l a-neck and predeton-atien do not occur. Thesecond valveis *op'en during all periodsof operation at which the primary valve i's-openect aud t-the secon'el valvecentrols the new of supplementary fuel hy-passed through the: primary val-veat' -highen manifold vacuums,- with the introductionei tuel being regulated by the intake: maniffuld' controllingsmovement: of thesecond valve.-

In the second. embodiment .of. present: in:- vention,, a. pain of diaphragm controlled valves are located within the reservoirciiorrcontrolling the flow of supplementary'iuel. 11111111117118 :res'ervoir: through :a conduit :intrr therengi-nevit- :selfi..." These"valvessarexlikewise'nperable zat-vadif :rerent' manifold :va-cuumsata effectithe qieedin :of; supplementary: fuel. to: theengineein accordiance with the operating conditions thereof. The primary valve is operable to close at relatively low manifold vacuums while the secondary metering valve remains open to selectively meter the supplementary fuel to the engine through arrestricted orifice placed in the conduit.

It is, therefore, an important object of the present invention to provide a supplementary fuel feeding device for internal combustion engines employing a plurality of diaphragm operated valves responsive to the intake manifold vacuum of the engine to control the flow of supplementary fuel from a reservoir into the engine.

Another important object of the present invention is to provide a supplementary fuel feeding device with a pair of successively closing metering valves actuated at different manifold vacuum ranges to feed varying amounts of supplementary fuel to the engine in accordance with the operating conditions of the engine.

It is a further important object of the present invention to provide a supplementary fuel feeding device regulated by a primary valve having a by-pass for permitting restricted flow even when the primary valve is seated and a second metering valve for controlling the flow from the by-pass.

A still further important object of the present invention is to provide a supplementary fuel feeding device with a pair of diaphragm controlled metering valves regulating flow of supplementary fuel with both valves being open at very low manifold vacuums to permit full metered flow of supplementary fuel under engine operating conditions most conducive to detonation and preignition and with one valve remaining open after the other valve has closed to meter restricted flow of the fuel under high vacuums.

On the drawings:

Figure 1 is a diagrammatic side elevation view of an internal combustion engine and fuel intake assembly equipped with a supplementary fuel feeding device of the present invention;

Figure 2 is a cross-sectional View, with parts shown in elevation, of the supplementary fuel feeding device of Figure l; p 7

Figure 3 i a fragmentary, enlarged crosssectional view similar to Figure 2 and illustrating the open position of the primary valve at relatively low manifold vacuum; and

Figure 4 is a cross-sectional of a modified form of supplementary fuel feeding device of the present invention as mounted on an internal combustion engine.

As shown on the drawings:

In Figure 1 reference numeral H) refers generally to a high compression internal combustion engine equipped with the customary fuel and aircharging assembly including an air cleaner H, a carburetor 12 receiving air from the cleaner H and main fuel from the feed line I3, the main fuel-air mixture being fed into the intake manifold i l of the engine ID for subsequent introduction into the combustion chambers of the engine. A relatively small tank [5 for supplementary anit-detonant fuel, such as a mixture of 85% water, methanol and 3 cc. per gallon tetraethyl lead is mounted in the fire wall N5 of engine Ill and is connected through line ll to a supplementary fuel feeding device N3 of the present invention.

The supplementary fuel feeding device 18 is illustrated in greater detailuin Figure '2 in which the device I8 is mounted on a pad I9a:of the air intake I9'of carburetor [2 in a position adjacent 4 the carburetor venturi 26 adapted to form a main fuel-air mixture from air entering the air intake l9 from cleaner H and fuel introduced into the venturi 20 from a conventional carburetor jet (not shown).

The supplementary fuelfeeding device II! as shown in Figure 2 includes a float 2| mounted in a chamber 22 defined by a bottom cup or bowl 23 and an upper casing 24, the bowl 23 being secured to the casing 24 by suitable means, as by screw 25 threadedly retained by the casing 24. The float 2| controls the introduction of supplementary fuel into the flow chamber 22 by means of an inlet needle valve 26 movable within an orifice housing 21' threadedly retained by casing 24 and defining a restricted orifice 21a. The orifice 21a is connected to an inlet port 28 receiving supplementary fuel through the tube if and the movement of the valve 26 into contact with the orifice 21a controlled by float support arm 29 pivoted to the casing by pin 35. Float chamber 22 is vented to atmospheric pressure through vent 3i communicating with the exterior atmosphere.

Casing 24 is provided with a depending boss 32 axially bored as at 32a and having a restricted orifice 33 formed in its lower extremity and communicating with an axial passage 34 provided by tube 35 extending axially through the depending boss 32. Tube 35 is vented to atmosphere through vent 36 and passage 34 is vented to atmosphere through holes 37 formed in the tube 35.

A spring chamber 38 is provided within the upper portion of the casing 24 and a boss 39, formed integrally with the casing 24, extends upwardly into the chamber 38. Boss 39 is axially bored to receive a diaphragm and spring-urged valve 45. Valve 45 is guided by boss 39 and is urged downwardly Within the boss by a diaphragm H secured in position to overly chamber 38 by a cover member 42 defining a recessed air chamber 43, vented to atmosphere through vent 4d, directly overlying the upper surface of diaphragm 4|. Diaphragm ll, secured to valve 48 by washer members Q5 and 45, is thus subjected to differential pressure conditions existing between atmospheric pressure of chamber 43 and manifold vacuum of chamber 38 vented to the intake manifold of engine in through tube 52 as hereinafter described.

The valve 40 is urged upwardly against the action of the diaphragm 4| by spring 48 surrounding the boss 39 and interposed between thefloor of chamber 38 and the lower washer member 46.

Chamber 38 is vented to manifold vacuum through a passage 49 communicating with vacuum chamber 50 formed in the cover 42 and having an upstanding hollow boss 5i, the interior of the boss 5! being vented to manifold vacuum by means of tube 52 vented to the intake manifold as at 52a below throttle valve 53. Thus, by means of the tube 52, both the chamber 59 and the chamber 38 are vented to manifold vacuum.

The chamber 54 is provided in the casing 24 and is vented to atmosphere as at 55. A second diaphragm 56 is clamped between the cover 42 and the body 24 to separate the chambers 5!] and 54. A sleeve 51 is threadedly retained in .the chamber 54, the sleevebeing axially apertured as at 58 and having a peripheral groove 59 joined to the bore 58 by communicating radial passages 80. A valve 51, having a conical seating face 62.

extends through the axial bore .58 and is secured to the diaphragm 58 by washer members 63 and 64.. A compression spring 55' is" interposedbeswim the-teas 51' amine-washer member as to seating fa ee -62 of :vaive -61 away from seated positic' and-a second spri-fi'g' ifi is interposed. betweensleeve- 51 and a hennet three-eerily retained on the other end of valve- '61, "the spring (it also urging "the valve t l awa from seated positron.

A conduit 68 connects the passagew threugh tube with the axialhere "5 8 of-sleeve ST and supplementary fuei-may- 'fiew trom the fiow chainheft-2 throughthe-restrictederifice e i nto passage fl throegnc'ondui't 6's, bore-5's, passages 68 greet/e59 and atubefte ccrine'cting greove ae vvith a t-urethra casiv tlo'n with the threat or" venturi Ill-through a seen-e H extending through the-air intake "t9 er'the engine -to-the venturi '20.

"f'heconipressionstren o'fthespringfltand the*'-resistance of thediaphragm '1 I are evaluated sdt'h'at the spring 48 w nse'a t the valve-KG from'its seated position against'seat W when-the manifold vacuum drops-hlevv a predetermined value on the order of from 35 tom nches; e1

water; Uponlilfti'ng' the valve "from "its "seated po's ion, as illustrated Figure '3, eommunica tier: will be" establishedfbetween the 'passaee 'ta and passage t8. supp'iementary fuel may-nay; through these passageways tn the venturi 2a for subsequent injection to the combustion chambers of" the engine. Assh'ewhji-n Figure-' 3, upon lifting of the valve by the ac on- -of'-'spring 4'8 metering -occurs' 'thrcugh the orifice Hand the opening afforded between the 'end ofthe valve 40' and the top er th tube as, 40 "is fully opened the *radial passageway it is close'd'hy thepcs sss and-no now through the bypassiconduit '1-2 is possible; However, -'Wh en valve is seated By diaphragm'ei at vacuums in "excess of that necessary tic-"overcome the resis'tarfo'e of the spring ilh'fl ui'd flowing":throughfthapassage e4- will be ey-passed throa h axiaibore'i and r'adial ecre t3 direotly'into' the passag'e'fifl. 'Th'e "radial passage l3 defines a restricted-orifice through which certain rest icted new may take place, the amount-cf flu-id "flowingthroughpassageia being less *thanthat fioWi'ng into *thep'assage "68 when the valve is 'ur'i'seate'das shown in Figure 3.

' "Valve 6 I, controlled by diaphragm 1E6" acting against the coiripress'ive stingth of compression springs 65 and may "also be-seated "from the open position of *Figure 2' "when the manifold vacuum in-chamber 5'0 exceeds a "given value,

'vihen the valve i unseated,oropen,' as'shown'in Figure-'2 fluid new is-estab-Iishedfronrthe passage 68 through here "58, 'radi'a'lbore- EU groove 59 into passa'gests and "f'ilandno zzle "l l. 'W'h'erithe valve 61 is-seated against the sleeve 51, new of fluid through the bore "58 is interrupted amino ful flow takes place. The comparative compres- Slv'e strength of the springs "65 andtfi is 'so' canlera'tedwith relation'to the resistance of the diaphragm -56 that theva-lve el is closed 'whenthe manifold vacuum 'g'reaterthanirom 110100 inches of water.

Thus, by means of the present iiiventiori'- supplemen-tar'y fuel fed from the fiovr-'hambe1"-'22 through the nozzle "II is controlled-in accord'ance with the manifold vacuum with "the two valves being operable under different manifold vacuums to insure the'ieedin'g of'siipplementary iue'l in' accordance with ithe; maniioldvacuuin etthe engin'ezas" vented through tube 52; 0x1 the 'rapi'd acceleration of i the engine or operation of the 4. IBore' TB fs incommunic-a- 'the'valve engine undemothemireunistaneeswhicirprodnce 9; lowr manifold vacuum very conducive ftoi 1131M;-

ie -regulated by the setting-of tlie valve fiil setting-is determined bythe manifold vacuum, thevalve if I- affording means for- 'the regulation-oi. flow in exact accordance with-' the operatiing haraeteristicsofthe engine; p In'theembodiment"illustrated in'Fignrel-ohthe d rawih-gs parts similar to oridentical to the emhodiinent' illustratedin-Figure "3'- are indicated by ident al reference numerals. this embodi- {men-t "f the-invention, the'float' chamber--"22 providedwitl rmeans for the intro duration of supelementary fuel into the "flow ehamber-to maina pond er 'fuel therein. This "regulating mechanism is as above "described and "employs valve- 2t-oontrolled by a iioat-2 f "and acting against anorifi'ce 21a. Floatehamber 221's defined by a main body section ill," a" casing "top' it and ah'ottom closure plate- TB. "The main body section F4 carries an upstanding central bossfll axiallyapertured at 1-8 'havin'ga "tu'b ['19 threadedlyretained"therein. Tube TBi's'provi'ded withanaxial 'passage'fih theitub'e 'fllfbeing vented totatmosphericpressurewithin the'fiow chamber 'fi bya vent iil-andthe passagefl'fl'bei'ngiventedat Y atmospheric pressurethroughiholes 82.

' interior ofzth'e flow chamber 22' throughrestricted orifices "85-h and'86b.- The sleeves '85 and '86 are also provided with outwardly (flared lower portions the and 860, respectively, extendingin'to "vacuum chambers 97 andwrespeetively, defined iby'rnating recesses"formed.iin'casihgasections14 a "and T6- The vacuum chambers 81 and 1 8 are vented through ports 189 and I, respectively, to a single .porlt' chaniberdl inecommunication'with theiintake' Jmanifold :of the engine through tube 92 ,eiiteiidinginto the intake manifold'as at93*below throttle valve 54. Tube 92 is.maint'ained ln posiltiorfwithin bottom closure plate 16 .by arm-t 94 gthreadedly retained Within depending boss 76a. 'Ihe sleeve85 carries a diaphragm Siextending across its lower flared portion 850" and the boss 86 carries a similarly positioneddiaphragm '96. A diaphragm Controlled metering valve"9'l 'Ii's mountedwithinisleeve 85 with its seatingface *QIaheingadaptedto close orificetiibupon downwardmovement'of thevalve caused bymovement oi the diaphragm 95 secured to thevalveiSl'l bywashermem'bersflii and-'99, The diaphragm 7 the action of spring I03 compressed between the upper surface of sleeve 80 and the bonnet I04 secured to the shank of valve I02.

Communication between the central aperture 85a. and the passage 80 is afforded through passages 105 extending radially to the sleeve 85 and passage 106 extending from boss 83 ton chamber I01 formed in the lower portion of the upstanding boss 'I'I. Similarly communication from the central portion 06 is provided through radial passage I08 and passage I09 extending through the boss to chamber I'I. A metering oriflceIIO is provided by a block positioned in the passage I09,

Each of the diaphragms 95 and 96 is subject to manifold vacuum on its undersurface by means of tube 92 and is subjected on its upper surface to atmospheric pressure within float chamber 22 together with the hydrostatic pressure generated by the amount of supplementaryfuel standing therein. The vacuum on the lower surface of each of the diaphragms tends to pull the valve secured thereto to closed position sealing off the chambers 850; and 86a to prevent the flow of supplementary fuel into these chambers. Springs I00 and I03 resist the downward pull exerted upon the valves 97 and I02, respectively, and tends .to urge the valve toward open position. The relative compressive strength of the spring-and the flow resistance of the diaphragm may be so adjusted that the valves 9'! and I02 will be closed at any given manifold vacuum, the springs I00 and I03 being suihciently strong below this vacuum to overcome the downward pull of the diaphragms 95 and 96, respectively.

In the present invention, the spring I00 and the diaphragm 95 are preferably of such strength thatthe valve 91 will be opened at manifold vacuums of less than 35 to 50 inches of water and so that flow may be obtained therethrough :at these vacuums or at lower vacuums. On the other hand, the valve I02 is preferably provided with diaphragm 9B and spring I03 of sufficient strength to maintain the valve in open position at any manifold vacuum less than from 70 to 100 inches of water. When the engine is operating under conditions such that the manifold vacuumis less than from about 35 to- 50 inches of water, both valves are open and feeding of supplementary fuel through the passages I06 and I09 into the chamber I01 from this chamber into the passage 80 through orifice Win, and the passage III leading to nozzle II2 may be accomplished and supplementary fuel may be injected through the nozzle II2 into the throat of venturi 20. However, if the manifold vacuum increases into the range varying from 35 to 50 inches of mercury up to and including 70 to 100 inches of water only the valve I02 will be opened and supplementary fuel flow will be obtained only through passage Hi9 and the restricted orifice I I0 into the tube 80 for subsequent injection into the venturi 20. At manifold vacuums of greater than 100 inches mercury, both valves will be closed and there would be no feeding of suppleinentary fuel into theventuri 20.

Thus, it may be seen that the present invention provides means whereby supplementary fuel is fed to the engine only during those periods of low'vacuum at which engine knock is likely to occur. Further, the amountofsupplementary -fuel injected into the engine is determined by a plurality; of valves disposed in the fuel feeding device and responsive to intakemanifold vacuum to the engine is varied in accordance with the anti-detonation requirements of the engine.

It will, of course, be understood that various details of construction may be varied through a wide range without departing from the principles of this invention, and it is, therefore, not the purpose to limit the patent granted hereon otherwise than necessitated by the scope of the appended claims. a

I- claim as my invention: Y

l. A device for feeding antiedetonant fluid to an internal combustion engine comprising a casing forcontaining a body of anti-detonant fluid, a conduit for connecting said body of fluid to the intake manifold of an internal combustion engine, and valve meanscontrolling the flow of said fluid through said conduit to-said engine, said valve means including a metering valve, a diaphragm for controlling said meteringvalve and having one side subjected to atmospheric pressure and the other side subjected to manifold vacuum to control movement of said valve in accordance with the operating characteristics of the engine, and a second metering valve, a diaphragm for controlling said second metering valve and having one side subjected to atmospheric pressure and the other side subjected to manifold vacuum to control movement of said valve in accordance with the operating characteristics of said engine, said valves being calibrated to successively close as intake manifold vacuum increases.

2. A device for feeding anti-detonant fluid to an internal combustion engine comprising a casing for containing a body of anti-detonant fluid, a conduit for connecting said body of fuel to a venturi located in the fluid intake of an internal combustion engine, and valve means located in said conduit for controlling the flow of said fluid therethrough, said valve means including a primary metering valve, a diaphragm for controlling said primary metering valve in accordance with differential pressure conditions, one side of said diaphragm subjected to atmospheric pressure and the otherlside subjected to manifold vacuum, said differential pressure conditions urging said valve to closed position, a spring urging said primary valve to open position against the resistance of said diaphragm, said spring being sumcient to overcome the resistance of said diaphragm at relatively low vacuums only, a secondary metering valve, a second diaphragm for said secondary metering valve for controlling the flow therethrough in accordance with differential pressure conditions, one side of said diaphragm being subjected to atmospheric pressure and the other side being subjected to manifold vacuum with said differential pressure conditions urging said valve to closed position, a second spring urging said valve to open position against the resistance of said diaphragm, said second spring being suihcient to overcome the resistance of said second diaphragm at manifold vacuum to establish flow through said secondary valve at manifold vacuumsconsiderably in excess of those sufficient to close said first valve.

3. A supplementary fuel feeding device comprising a casing for containing a body of supplementary fuel, a conduit for connecting said body of fuel to the intake manifold of an internal combustion engine,and a pair of valves for controlling the introduction of supplementary fuel into said conduit for subsequent introduction into the intakemanifold of the engine, said valves so that the amount of supplementary fuel=fed being responsive to the engine intake Imanifold g9. vacuum with one of said valves establishing new of supplementary fuel at relatively low vacuums particularly conducive to knock and interrupting the flow of supplementary fuel upon'an-increase, of. engine intake manifold vacuum, the other of said valvesestablishing flow of supplementary fuel at all conditions under which said first valve 'isopen and being operable at relatively high,

vacuums to continue-the feeding of supplemen-v taryfuel at vacuums inexcess of thosesuflicient to close said first valve.

' 4.iA device for feeding anti-detonant fluid to an internal combustion engine comprising a casing for containing a body of antiedetonant fluid, :a conduit for connecting saidbody of fluid. to theintake manifold-of an internal combustion-engine, and valve-means, for controlling the flow of said fluid from said body, into said con duit said valve means including a primary valve disposed in said conduit and operableto establish flow of said fluid through said conduit at relatively low manifold vacuums while interruptingthe flow of fluid at relatively high manifold vacuums, said primary valve having a bypass conduit for establishing a restricted flow of said fluid when the'main flow of fluid therethrough is interrupted, and a secondary valve locatedin said, conduit beyondsaid primary valve andoperable to remain open under all engineoperating conditions at which said main valve is open, and.

remaining open at manifold vacuumsinexcess of those sufiicient to interrupt the .flow of fluid through said primary valve to meter the flow of.

fluid through said by-pass, said secondary ,valve'f also being operable .atv .high manifold vacuums tointerrupt the flow of anti-detonant fluid when the engine is operating under conditionsnot conducive toengine pro-ignition anddetonation.

5.. In a device for feeding .anti-detonant fluid. to aninternal combustion enginehaving a casing for containing a body of anti-detonantfluidand a conduit for connectingsaid bodyof fluidto .the

intake manifold of an internal corrlbustionengine,v

of said first valve being calibrated to urge said valve toopen position only at low manifold vacuums particularly conducive to-engine detonation and pre-ignition, and the diaphragm and valve controlling said second valve being calibrated to establish flow of said fluid at intermediate and low manifold vacuums conducive to engine predetonation and knock, said second valve serving to meter flow from said first valve at low vacuums and from said means at higher vacuums, whereby the amount of anti-detonant fluid ejected into said engine may be varied in accordance with the intake manifold vacuum of said engine.

6. In a supplementary fuel feeding device having a casing for containing a body of supplementary fuel, a conduit for connecting said body of fuel to the intake manifold of an internal combustion engine, :and valve means for. controlling the introduction of supplementary fuel through said conduit in accordance; with the manifold vacuum of said engine, additionalvalve means for controlling the flow of supplementary fuel comprisinga valve, a diaphragm secured tor-said valve and subjected to differential atmospheric and intake manifold pressure to urge said valve, to closed position, and a compression spring urging said valve into position against the action. of said diaphragm, said diaphragm and said spring being calibrated to establish flow through saidv second valve under'intake manifoldvacuums suflicient, to close said first valve.

' '7. A supplementary fuel feeding device oom prising a casing; for containing a body of supplementary fuel, a conduit, connecting said body of. fuel to the intake manifold of an internal, combustion engine, 'valve means located in said casing for controlling the-flow of supplementary fuel from said-body .into said ointakemanifold, said valve means including a first valve and a, second valve controlled by diiferentialpressure conditions existing between; atmospheric; pressure andengineintake manifold pressure, one.-of said valves being operable ;to establish flow oi -supple? 8, A supplementary fuel feeding deviceoom prising a casing forcontaining a body of rsup plementary fuel, a conduit formcon-nectingwsaid body of fuel to theintakem'anifold ofan-intern'al combustion engine, and valve means for controlling the flow of supplementary fuel- :from said body to said intake manifold including .a first valveand asecond valve submerged in said body of supplementary fuel, and a diaphragm for each of saidvalves subjected .on one :side to engine intake manifold vacuum. and subjected. on its other side ;to atmosphericgpressure plus; hydrostatic pressureof said body of supplemene. tary fuel, said first valve being operable :at'low engine intake manifoldyacuumsto .meter supplementary .fuelthrough "said conduit :and being closed at greater intake-manifold vacuums, to:

interrupt thev flow of supplementaryfuel throughv said conduit,,said.isec.ond valve being operable. to ;es.tablish flow. of, supplementary fuelqinto sa-id conduit; at intakemanifold :vacuums .in excess of those;sufficientztorseat. said first valve, and .said' second :valvel also :being operable: at elevated engine .:intake:manifold' vacuums to. interrupt: the flow; .of supplementaryfueli under engine operating conditions: not'nonducive. to knock or predetonation. I

9.,A feeding, device actuated byiintake manifold pressure of an internal combustion engine which comprises a casing having a float chamber, means in said casingproviding adischargepassage communicating with the lower: portionof saidcfloat chamber, a fixed orifice'in said dis charge passagemeansfor bleedingairtintofluid flowing through said discharge passage, a plurality of valves controlling flow from said float chamber through said discharge passage, and an actuator for each of said valves adapted to be operatively vented to the intake manifold of an internal combustion engine for successively clos- 10. A supplementary fuel feed device for an internal combustion engine adapted to be actuated by intake manifold pressure of the engine which comprises a casing having a chamber for a pond of supplementary fuel and a discharge outlet, means defining a passageway from the lower portion of said chamber to the discharge outlet of said casing, a fixed orifice in said passageway, means for venting air into said passageway for admixture with fuel metered by the fixed orifice, a first vacuum-operated valve in said passageway regulating fiow of air and fuel, a second vacuum-actuated valve in said passageway regulating flow from the first valve to the discharge outlet, said valves being constructed and arranged so that the first valve will close at relatively low vacuums while the second valve will remain open until appreciably high vacuums are reached in the engine, and said first valve having a by-pass metering means therethrough to meter fuel to the second valve when the first valve is closed.

11. A supplementary fuel feeding device for an internal combustion engine comprising a casing for containing a body of supplementary fuel, a conduit communicating with said casing for withdrawing fuel therefrom, a valve seat in said conduit, 9. first diaphragm controlled valvecoacting with said seat and responsive to manifold vacuum of said engine to establish full fuel flow through said conduit at low vacuums only, means for by-passing lesser amounts of fuel past said first valve and through said conduit at intake manifold vacuums in excess of those which initiate flow through said first valve, a by-pass chamber for receiving fuel from said conduit, means for introducing fuel from said chamber into said engine, and a second diaphragm controlled valve interposed between said conduit and said by-pass chamber, said second valve being responsive to engine intake manifold vacuum to control fuel flow to said chamber from said bypassing means.

12. A supplementary fuel feeding device for injecting supplementary fuel to the intake manifold of an internal combustion engine, comprising a casing for containing a body of supplementary fuel, a conduit for withdrawing fuel from said casing, means responsive to engine intake manifold vacuum for establishing full fuel flow through said conduit at low manifold vacuums and a fixed restricted flow at higher manifold vacuums, a by-pass chamber for receiving fuel flow from the conduit, means responsive to engine intake manifold vacuum for controlling fuel fiow through said chamber, said means Y being effective to stop fuel flow under the influence of high manifold vacuums, and a conduit for introducing fuel from said chamber into the intake manifold of said engine, the co-action of said manifold vacuum responsive means accurately correlating the introduction of supplementary fuel to the engine in accordance with the actual operating conditions of the engine to prevent engine detonation and pre-ignition.

13. A feed device for an internal combustion engine which comprises casing means having a liquids chamber and a discharge passageway communicating with said chamber, fixed orifice means in said discharge passageway, air bleed means in said discharge passageway for admixing air with liquid flowing therethrough from said chamber, at least a pair of valves controlling flow from said chamber through said discharge passageway, means responsive to intake manifold pressure for closing one of said valves with mani fold pressure decreased to a predetermined value, and means responsive tointake manifold pressure for closing another of said valves with manifold pressure decreased to a value less than said predetermined value. r e

14. A feed device for an internal combustion engine which comprises a casing defining a liquids chamber, and having a discharge passageway leading from the lower portion of said chamber,

at least a pair of valves controlling fiow from said chamber through said discharge passageway, means responsive to intake manifold pressure for closing one of said valves with manifold pressure decreased to a predetermined value, and means responsive to intake manifold pressure for closing another of said valves with manifold pressure decreased to a value less than said predetermined value.

15. A fuel feed device for the carburetor of an internal combustion engine which comprises a casing defining a float chamber, a pair of valves controlling flow out of the bottom of said float chamber, a first spring urging one of said valves open, a first diaphragm subjected to intake manifold vacuum for closing said one of said valves with manifold vacuum increased to a predetermined value, a second spring urging the other of said valves open, a second diaphragm subjected to intake manifold vacuum for closing said other of said valves with manifold vacuum increased to a value greater than said predetermined value, and a common discharge port for said valves.

' DAVID E. ANDERSON.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Ericson July 26, 1949 

